System and method for processing data of any external services through api controlled universal computing elements

ABSTRACT

Disclosed herein are systems and methods for multi-system connectivity and automation via universal computing elements. Universal computing elements may comprise an object queue, one or more counters, and a function operating on parameters of objects in the object queue. Universal computing elements may be interconnected into processes of arbitrary complexity. Universal computing elements may facilitate modular and scalable business process development, including application programming interface and database connectivity.

RELATED APPLICATIONS

This application is a Continuation-In-Part application under 35 U.S.C. §120 of U.S. application Ser. No. 16/252,075 filed on Jan. 18, 2019,which is a Continuation-In-Part application of U.S. application Ser. No.15/268,802 filed on Sep. 19, 2016, which claims the benefit under 35U.S.C. § 119(e) of U.S. Provisional Application No. 62/221,124 filed onSep. 21, 2015.

Related U.S. application Ser. No. 16/252,075 filed on Jan. 18, 2019 isalso a Continuation-In-Part application under 35 U.S.C. § 120 of U.S.application Ser. No. 15/077,626 filed on Mar. 22, 2016, which claims thebenefit under 35 U.S.C. § 119(e) of U.S. Provisional Application No.62/137,079 filed on Mar. 23, 2015.

This application further claims the benefit under 35 U.S.C. § 119(e) ofU.S. Provisional Application No. 62/213,114 filed on Jun. 21, 2021.

This application is a Continuation-In-Part application under 35 U.S.C. §120 of U.S. application Ser. No. 16/027,926 filed on Jul. 5, 2018, whichis a Continuation-In-Part application of U.S. Ser. No. 15/268,802 filedSep. 19, 2016, which claims the benefit under 35 U.S.C. § 119(e) of U.S.Provisional Application No. 62/221,124 filed on Sep. 21, 2015.

Related of U.S. application Ser. No. 16/027,926 filed on Jul. 5, 2018 isalso a Continuation-In-Part application of U.S. application Ser. No.15/077,626 filed Mar. 22, 2016, which claims the benefit under 35 U.S.C.§ 119(e) of U.S. Provisional Application No. 62/137,079 filed on Mar.23, 2015.

It is intended that the referenced application may be applicable to theconcepts and embodiments disclosed herein, even if such concepts andembodiments are disclosed in the referenced application with differentlimitations and configurations and described using different examplesand terminology.

FIELD OF DISCLOSURE

The present disclosure relates to computer-implemented systems andmethods for multi-system connectivity and automation. More specifically,the present disclosure relates to multi-system connectivity andautomation via collections of one or more universal computing elements,each of which may comprise an object queue, one or more counters, and afunction operating on parameters of objects in the object queue.

BACKGROUND

In many ways, existing software and business process developmentparadigms can be rigid and siloed, burdened by inertia, slow to provideactionable business intelligence, difficult to scale, and difficult fornon-coders to interact with.

Traditionally, many such systems have been developed without muchconsideration of how to combine them with each other, especially betweendifferent vendors (both hardware and software). Many of theconfiguration values that are parameters of business processes arehardcoded, making changes slow and expensive. The inertia of a heavy,slow-to-change, existing codebase can siphon information technologybudgets away from innovation. In addition, many existing systems arebatch-based and their response is determined by the batch frequency, notby the fluid, breathing reality of realtime data. Many existing systemsalso struggle with scalability and concurrency.

Further, some software development paradigms allow for powerful,flexible algorithm development, and some allow for no-code/low-codeapproachability. It may be advantageous for a system to provide both.Indeed, systems that may variously address the above issues, and others,may provide advantages over the traditional approaches.

In view of at least the above shortcomings, a need exists for systemsand methods for multi-system connectivity and automation via universalcomputing elements.

BRIEF OVERVIEW

This brief overview is provided to introduce a selection of concepts ina simplified form that are further described below in the DetailedDescription. This brief overview is not intended to identify keyfeatures or essential features of the claimed subject matter. Nor isthis brief overview intended to be used to limit the claimed subjectmatter's scope.

Systems and methods for multi-system connectivity and automation viauniversal computing elements (UCEs) may be provided. A UCE consistentwith the embodiments of the present disclosure may be operative withvarious methods, systems, and computer-readable media (collectivelyreferred to herein as the “platform” or the “disclosed platform”).

The platform may comprise one or more objects, each of which may becharacterized by its parameters. The platform may comprise one or moreuniversal computing elements (UCEs), each of which may comprise a queuefor objects, one or more counters related to objects in the queue, and afunction operating on object parameters and/or counters.

UCEs may operate in a manner analogous to state machines. Each object inthe queue of a UCE may be conceptualized as being in a particular stateat any particular time. Such a state may comprise the object's currentparameters and their values. Such parameters may include an identifierfor the UCE in which the object is queued. A UCE itself may also beconceptualized as being in a particular state at any particular time.Such a state may comprise the object constituents of its queue and thecurrent values of counters related to objects in the queue. A UCE'sfunction may transition objects to new states.

By way of non-limiting example, a function may change the state of anobject by adding, modifying, or removing a parameter of that object. Byway of another non-limiting example, a function of a first UCE maychange the state of an object so that it may “flow” or “proceed” fromthe first UCE to a second “interconnected” UCE by changing a parameterof that object from identifying the first UCE to identifying the secondUCE. Both of the above example state changes may be mutually consistentwith each other and, indeed, may in some embodiments be engendered bythe operation of a single UCE's function.

UCEs (also sometimes referred to as “nodes”) may be connected in myriadways to form processes, which may be thought of as collections ofinterconnected UCEs. In some embodiments, the connectivity of UCEs maybe simple and linear. In one example, objects may proceed from astarting node through one or more subsequent nodes to an end node,functions operating on objects each step of the way. In furtherembodiments, the connectivity of UCEs (and of processes), need not besimple nor linear. The interconnections between UCEs (and betweenprocesses) may be complex, including loops, branches, nesting, andmultiple end points.

Objects (also sometimes referred to as “tasks”), characterized byparameters (for example, name: value pairs), may flow into a node'squeue from a variety of sources. The variety of sources may include, butnot be limited to, for example, other processes, application programminginterfaces (APIs) and various data sources (databases, etc.), and humaninput.

Consistent with embodiments disclosed herein, a node may comprise atleast one counter. A node's counters may be used to, by way ofnon-limited example, keep track of data about the objects currently inthat node's queue. A non-limiting example of data related to which anobject may keep a counter is the number of objects in the queue. Anothersuch example may be the timestamp of each object's entry into the queue.Another such example may be how many of the objects have parameters thatmeet particular criteria.

A function (which, in certain contexts may be disclosed or utilized asat least one “rule”), consistent with the embodiments herein may beassociated with a node. The function may be, for example, but is notlimited to, a conditional, API call, code snippet, or call to anotherprocess. Functions may be configured to operate on (parameters of)objects that enter a UCE's queue or on the UCE's counters. In someembodiments, functions may serve to alter parameters of objects, as maybe the case when an API is called and returns pertinent data to add tothe object about which it was called.

The platform may provide, by way of non-limited example, an APIinterface, analytics, dashboarding, and data visualizationfunctionality. The platform may provide various measures of, andinterfaces to, processes in realtime.

One objective of the disclosed platform may be to provide a UCEcomprising a queue of objects, object counters, and a function operatingon at least one of the objects.

Another objective of the disclosed platform may be to provide for aplurality of connected UCEs capable of assembling algorithms ofarbitrary complexity.

Another objective of the disclosed platform may be to provide a Turingcomplete computational system.

Another objective of the disclosed platform may be to provide nestable,independent, state machines.

Another objective of the disclosed platform may be to providemulti-system connectivity and automation of workflows via aninterconnected plurality of UCEs.

Another objective of the disclosed platform may be to connect with aplurality of services and data sources via application programminginterface (API).

Another objective of the disclosed platform may be to provide UCEshaving particularized functionalities such as conditionals, API calls,mathematical expressions, variable get/set, and arbitrary code.

Another objective of the disclosed platform may be to provide acloud-based platform that can be managed via anonymized/non-identifyingdata.

Another objective of the disclosed platform may be to scalablyaccommodate high request per second workloads.

Another objective of the disclosed platform may be to provide forno-code/low-code functionality that may enhance the efficiency, speed,or division of labor in software and process development.

Another objective of the disclosed platform may be to provide rapidprototyping by building complex systems from UCEs.

Another objective of the disclosed platform may be to providemulti-purpose cloud platform for development, maintenance, management,execution, monitoring and optimization of software for automatic orautomated business processes.

Another objective of the disclosed platform may be to provide processversioning for the platform's processes.

Another objective of the disclosed platform may be to provide for thepossibility of storing data within the platform.

Another objective of the disclosed platform may be to provide a userinterface to the platform that permits “drag-and-drop” creation,selection, interconnection, and modification of UCEs.

Another objective of the disclosed platform may be to provide a userinterface to the platform that provides pertinent information and inputsupon the selection of a UCE.

Another objective of the disclosed platform may be to provide errorhandling for API calls and other actions performed by the platform.

Another objective of the disclosed platform may be to describe changesof the relative states of data within the platform.

Another objective of the disclosed platform may be to utilize statediagrams in the manner of a database, such that the logic of an object'stransition between different states described, and further that statetransitions may trigger the launch of processes.

Another objective of the disclosed platform may be to permit increasesin efficiency by shifting a process into an in-memory configuration.

Another objective of the disclosed platform may be to enable analytics,dashboarding, and data visualization functionality for UCEs.

The disclosed platform may provide technical advantages overconventional solutions. One such advantage may be the scalability ofUCE-based processes to possibly handle thousands, tens of thousands, ormore of concurrent tasks.

Another such advantage may be the breadth of the platform's trackabledata and speed of access of analytics, dashboarding, and datavisualization to the same.

Another such advantage may be the ability for a queue to store anarbitrary number of objects.

Another such advantage may be the breadth of functionality available toUCE functions.

Another such advantage may be the possibility for simultaneous,multifarious sourcing of objects.

Another such advantage may be the possibility of accepting and handlingobjects with heterogenous data structures.

Another such advantage may be the limitless capacity for sequentializingobjects in queues via custom counters.

Both the foregoing brief overview and the following detailed descriptionprovide examples and are explanatory only. Accordingly, the foregoingbrief overview and the following detailed description should not beconsidered to be restrictive. Further, features or variations may beprovided in addition to those set forth herein. For example, embodimentsmay be directed to various feature combinations and sub-combinationsdescribed in the detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this disclosure, illustrate various embodiments of the presentdisclosure. The drawings contain representations of various trademarksand copyrights owned by the Applicants. In addition, the drawings maycontain other marks owned by third parties and are being used forillustrative purposes only. All rights to various trademarks andcopyrights represented herein, except those belonging to theirrespective owners, are vested in and the property of the Applicants. TheApplicants retain and reserve all rights in their trademarks andcopyrights included herein, and grant permission to reproduce thematerial only in connection with reproduction of the granted patent andfor no other purpose.

Furthermore, the drawings and their brief descriptions below may containtext or captions that may explain certain embodiments of the presentdisclosure. This text is included for illustrative, non-limiting,explanatory purposes of certain embodiments detailed in the presentdisclosure. In the drawings:

FIG. 1A illustrates a conceptual diagram of a universal computingelement in accordance with various embodiments of the presentdisclosure.

FIG. 1B illustrates a conceptual diagram of a process comprisinguniversal computing elements in accordance with various embodiments ofthe present disclosure.

FIG. 1C illustrates a conceptual diagram of a process comprisinguniversal computing elements in accordance with various embodiments ofthe present disclosure.

FIG. 2A illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 2B illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 3 illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 4 illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 5 illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 6 illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 7 illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 8A illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 8B illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 8C illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 9A illustrates a flowchart diagram of an example method inaccordance with various embodiments of the present disclosure.

FIG. 9B illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 9C illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 10 illustrates a block diagram of the architecture of an exampleimplementation of the disclosed platform in accordance with variousembodiments of the present disclosure.

FIG. 11 illustrates a block diagram of the architecture of an exampleimplementation of the disclosed platform in accordance with variousembodiments of the present disclosure.

FIG. 12 illustrates simplified activity diagram of the interpretationalgorithm in an example implementation of the disclosed platform inaccordance with various embodiments of the present disclosure.

FIG. 13A illustrates a block diagram of an example implementation of thedisclosed platform in accordance with various embodiments of the presentdisclosure.

FIG. 13B illustrates an example interface to the disclosed platformshowing an example implementation in accordance with various embodimentsof the present disclosure.

FIG. 14 illustrates a block diagram of a platform including a computingdevice in accordance with various embodiments of the present disclosure.

DETAILED DESCRIPTION

As a preliminary matter, it will readily be understood by one havingordinary skill in the relevant art that the present disclosure has broadutility and application. As should be understood, any embodiment mayincorporate only one or a plurality of the above-disclosed aspects ofthe disclosure and may further incorporate only one or a plurality ofthe above-disclosed features. Furthermore, any embodiment discussed andidentified as being “preferred” is considered to be part of a best modecontemplated for carrying out the embodiments of the present disclosure.Other embodiments also may be discussed for additional illustrativepurposes in providing a full and enabling disclosure. Moreover, manyembodiments, such as adaptations, variations, modifications, andequivalent arrangements, will be implicitly disclosed by the embodimentsdescribed herein and fall within the scope of the present disclosure.

Accordingly, while embodiments are described herein in detail inrelation to one or more embodiments, it is to be understood that thisdisclosure is illustrative and exemplary of the present disclosure andare made merely for the purposes of providing a full and enablingdisclosure. The detailed disclosure herein of one or more embodiments isnot intended, nor is to be construed, to limit the scope of patentprotection afforded in any claim of a patent issuing here from, whichscope is to be defined by the claims and the equivalents thereof. It isnot intended that the scope of patent protection be defined by readinginto any claim a limitation found herein that does not explicitly appearin the claim itself.

Thus, for example, any sequence(s) and/or temporal order of stages ofvarious processes or methods that are described herein are illustrativeand not restrictive. Accordingly, it should be understood that, althoughstages of various processes or methods may be shown and described asbeing in a sequence or temporal order, the stages of any such processesor methods are not limited to being carried out in any particularsequence or order, absent an indication otherwise. Indeed, the stages insuch processes or methods generally may be carried out in variousdifferent sequences and orders while still falling within the scope ofthe present disclosure. Accordingly, it is intended that the scope ofpatent protection is to be defined by the issued claim(s) rather thanthe description set forth herein.

Embodiments of the present disclosure may provide a hardware andsoftware platform operative by a set of methods and computer-readablemedia comprising instructions configured to operate computing elementsin accordance with the methods. The present disclosure depicts and/ordescribes at least one example method of a plurality of methods that maybe performed by at least one of the aforementioned computing elements.Various hardware components may be used at the various stages ofoperations disclosed with reference to each computing element.

For example, although methods may be described to be performed by asingle computing device, it should be understood that, in someembodiments, different operations may be performed by differentnetworked elements in operative communication with the computing device.For example, at least one computing device may be employed in theperformance of some or all of the stages disclosed with regard to themethods. Similarly, an apparatus may be employed in the performance ofsome or all of the stages of the methods. As such, the apparatus maycomprise at least those architectural components as found in thecomputing device.

Furthermore, although the stages of the example method(s) disclosedherein are disclosed in a particular order, it should be understood thatthe order is disclosed for illustrative purposes only. Stages may becombined, separated, reordered, and various intermediary stages mayexist. Accordingly, it should be understood that the various stages, invarious embodiments, may be performed in arrangements that differ fromthe ones claimed below. Moreover, various stages may be added or removedfrom the without altering or deterring from the fundamental scope of thedepicted methods and systems disclosed herein.

Additionally, it is important to note that each term used herein refersto that which an ordinary artisan would understand such term to meanbased on the contextual use of such term herein. To the extent that themeaning of a term used herein—as understood by the ordinary artisanbased on the contextual use of such term—differs in any way from anyparticular dictionary definition of such term, it is intended that themeaning of the term as understood by the ordinary artisan shouldprevail.

Regarding applicability of 35 U.S.C. § 112, ¶6, no claim element isintended to be read in accordance with this statutory provision unlessthe explicit phrase “means for” or “stage for” is actually used in suchclaim element, whereupon this statutory provision is intended to applyin the interpretation of such claim element.

Furthermore, it is important to note that, as used herein, “a” and “an”each generally denotes “at least one,” but does not exclude a pluralityunless the contextual use dictates otherwise. When used herein to join alist of items, “or” denotes “at least one of the items,” but does notexclude a plurality of items of the list. Finally, when used herein tojoin a list of items, “and” denotes “all of the items of the list.”

The following detailed description refers to the accompanying drawings.Wherever possible, the same reference numbers are used in the drawingsand the following description to refer to the same or similar elements.While many embodiments of the disclosure may be described,modifications, adaptations, and other implementations are possible. Forexample, substitutions, additions, or modifications may be made to theelements illustrated in the drawings, and the methods described hereinmay be modified by substituting, reordering, or adding stages to thedisclosed methods. Accordingly, the following detailed description doesnot limit the disclosure. Instead, the proper scope of the disclosure isdefined by the appended claims. The present disclosure contains headers.It should be understood that these headers are used as references andare not to be construed as limiting upon the subjected matter disclosedunder the header.

The present disclosure includes many aspects and features. Moreover,while many aspects and features relate to, and are described in, thecontext such as authentication workflows, communication workflows, chatand chatbot workflows, finance and banking workflows, and logisticsworkflows, embodiments of the present disclosure are not limited to useonly in this context. Other examples may include customer relationshipmanagement workflows, ecommerce workflows, robotics workflows, rideshareand transportation workflows, software development workflows, etc.

I. OVERVIEW

Consistent with embodiments of the present disclosure, systems, methods,and computer-readable media for multi-system connectivity and automationvia universal computing elements—platform 100—are provided. Variousembodiments of platform 100 are described herein. Components of platform100 as presented in the following disclosure may be integrated, usedindependently, in conjunction with, used separately, or in connectionwith other embodiments they are not shown or described as functioningwith. Any aspects of one embodiment may or may not be usedinterchangeably with other elements and aspects of a platform 100 aspresented in the present disclosure.

Some or all of the following components may be present in embodiments ofthe present disclosure. The below description is in no way intended tolimit the components that may be present in addition or in alternativeto the listed components, nor to require that any particular componentbe included in a form described below.

a. Platform 100

Platform 100 may, in various aspects and embodiments, be conceptualizedas a collection of one or more interconnected universal computingelements (or “UCEs”) 110. An example conceptual diagram of a UCE (or“node”) 110 is depicted in FIG. 1A. Consistent with the depiction inFIG. 1A, UCEs 110 may comprise a queue 120 for objects (or “tasks”) 130.Objects 130 may be characterized by parameters 140 (e.g. name: valuepairs). Counters 150 may store data about queue 120 or objects 130. Afunction (or “rule”) 160 may operate on parameters 140 of the UCE's 110objects 130 or on counters 150 of the UCE 110.

UCEs 110 may operate in a manner analogous to state machines. Eachobject 130 in the queue 120 of a UCE 110 may be conceptualized as beingin a particular state at any particular time. Such a state may comprisethe object's 130 current parameters 140 and their values. Suchparameters 140 may include an identifier for the UCE 110 in which theobject is queued. A UCE 110 itself may also be conceptualized as beingin a particular state at any particular time. Such a state may comprisethe object 130 constituents of its queue 120 and the current values ofcounters 150 related to objects 130 in the queue 120. A UCE's 110function 160 may transition objects 130 to new states. By way ofnon-limiting example, a function 160 may change the state of an object130 by adding, modifying, or removing a parameter 140 of that object130.

In various embodiments, a UCE 110 may form an outbound connection withanother UCE 110 or with itself. By way of another non-limiting example,a function 160 of a first UCE 110 may change the state of an object 130so that it may “flow”, “proceed”, or “be released” from the first UCE110 to a second “interconnected” UCE 110 by changing a parameter 140 ofthat object 130 from identifying the first UCE 110 to identifying thesecond UCE 110. The second UCE 110 may be said to “accept” the object130. By way of another non-limiting example, an object 130 may remain ina UCE's 110 queue 120 until acted upon by the UCE's 110 function 160. Byway of another non-limiting example, an object 130 may remain in thequeue 120 an “end” node 110 indefinitely.

UCEs 110 may be combined together into collections of UCEs 110 that forma process 170. In a process 170, objects 130 may be routed among UCEs110, passing through their respective queues 120, wherein theirparameters 140 may be operated upon and modified by the UCEs' 110respective functions 160. The path may be simple, as depicted forexample in FIG. 1B, but need not be. Processes 170 may be arbitrarilycomplex, including include loops, branches, nesting, multiple endpoints,etc., as depicted for example in FIG. 1C (which also depicts calls,represented by dotted lines, from UCEs 110 to other processes 170).

FIGS. 2A-B depict an example interface to platform 100 showing exampleimplementation 200. In this example implementation 200, UCE nodes 110(labeled for clarity in FIG. 2B with an “N”) are collected into anexample process 170 for authenticating a user via their phone number.This example implementation 200 depicts nodes 110 subspecialized (asdiscussed further infra) and variously connected. Also depicted arevarious nodes' 110 pertinent parameters 140 (see boxes called out byarrows). This example implementation 200 is explored in greater detailinfra following a brief overview of some features platform 100 maycomprise, as well as some examples involving the same.

i. Brief Overview of Features Platform 100 May Comprise

By way of non-limiting example, a queue 120 may be generallyconceptualized, in various embodiments, as representing a collection oftasks 130 to or about which a node 110 is to do something (i.e. viafunction 160). Objects 130 may enter a UCE's 110 queue 120 from avariety of sources, which may include the results of an API call 131(which may be generalized as encompassing a broad array of data sourcesand external processes), human input 132, another UCE 110 a, or anotherprocess 170 a.

By way of non-limiting example, objects 130 may be generallyconceptualized, in various embodiments, as representing a discreteconceptual unit about which something is to be done. Objects 130 may begenerally conceptualized this way both in the sense of an individual UCE110 “doing” something, in its course of operation, to or about object130, and in the more general sense of object 130 existing in process 170as a task 130 to be purposefully acted upon. Some examples may includeas a caller to be routed to an operator, a loan borrower to be checkedfor creditworthiness, a chat participant to be authenticated, etc. Moreabstract examples may include a currency exchange rate to be polled,location-specific weather forecast to be queried, an HTTP connection tobe kept alive, etc.

By way of non-limiting example, parameters 140 may be generallyconceptualized, in various embodiments, as characterizing the currentstate of an object 130, such as, for example, a caller's initial calltimestamp, a loan borrower's tax ID, a chat participant's chat instanceID, an exchange rate request's from and to currencies, a weatherforecast request's geographic information, a Hypertext Transfer Protocol(HTTP) connection's Uniform Resource Locator (URL), etc.

Still consistent with embodiments of the present disclosure, parameters140 may be added or modified by UCEs 110. For example while a caller'sinitial call timestamp may stay the same throughout a process 170, aparameter 140 signifying the number of times the caller has beentransferred may increment. An object 130 representing a chat participantmay be updated with the parameter 140 of the participant's response to arequest for their phone number to authenticate them. An object 130representing a weather forecast request may be updated with theparameter 140 of current temperature, returned from a call to a weatherAPI. In another non-limiting example, as an object 130 proceeds througha process 170, parameters 140 may be altered by a first UCE 110. If theobject 130 passes into the queue 120 of a subsequent UCE 110, thesubsequent UCE 110 may “see” the parameters 140 of the object 130 asaltered by the first UCE 110.

By way of non-limiting example, counters 150 may be generallyconceptualized, in various embodiments, as counting or ordering objects130 with respect to queue 120, such as the number of objects 130 inqueue 120, the timestamp of entry of an object 130 into the queue 120.

By way of non-limiting example, a function 160 may be generallyconceptualized, in various embodiments, as the aspect of a UCE 110 thatis doing the “doing” that UCE 110 does to or in association with objects130 that enter its queue 120. Functions 160 may comprise operations suchas mathematical expressions, conditionals, getting and settingvariables, running code (e.g., Javascript, Java, Erlang, etc.).

In yet further embodiments, functions 160 may be configured forestablishing connections to external systems (e.g. API calls, databaseconnections, code versioning repositories), calling or modifying otherprocesses 170, asking for input from a user, etc. A function 160 may, aspart of its operation, alter one or more parameters 140 of an object 130to which it is applied.

In various embodiments, upon the execution of a first UCE's 110 function160, an object 130 may pass to a subsequent one of the plurality of UCEs110 b (which may include a loopback to the same UCE 110). Subsequent UCE110 b may apply a function 160 to the object 130. Additionally oralternatively, subsequent UCE 110 b may be an end state (i.e. an endnode 110). In various embodiments, there may be at least oneinterconnection between each UCE 110 and at least one other UCE 110,each interconnection comprising an outbound UCE 110 and aninterconnection function of the outbound UCE 110 identifying one of theplurality of UCEs 110 b.

By way of non-limiting example, a first UCE's 110 function 160 maycomprise an interconnection that may identify one of the plurality ofUCEs 110 b that may comprise a process 170. The interconnection may beconfigured to set one of the one or more parameters 140 of a queuedobject 130 to which the function 160 is applied to the UCE 110 bidentified by the interconnection. In this example, setting a “nodeidentifier” parameter 140 to UCE 110 b may precipitate the release ofthe object 130 from the queue 120 of the first UCE 110 to the queue 120of the subsequent, identified UCE 110 b.

In some embodiments, an object 130 may pass to one of potentially manyUCEs 110 b, depending on the one to arbitrarily many exit statespossible for a function 160. This can be as simple as shunting offerror-state objects 130 to an error handling node 110, or as complex aslogic/code dictates.

For example, function 160 may set a parameter 140 of objects 130 thatpass through its queue 120. As another example, function 160 may get anobject 130 from the queue 120 of a UCE 110 from another process 170. Asanother example, function 160 may apply a conditional to a parameter 140of each object 130 that enters the queue 120, such as whether its valueexceeds a threshold, or whether the returned text string matches one ofvarious string values. The outcome of a conditional function 160 may beused to direct the flow of outgoing objects 130 to interconnected nodes110. As an example, a conditional may have a plurality of outcomes, eachoutcome providing an outbound interconnection to a node 110.

In a non-limiting, general example of the operation of a UCE 110, queue120 may take in objects 130 representing prospective loan borrowers, viamanual data entry 132, the objects 130 having parameters 140 such asname and tax ID. UCE 110 may apply the function 160 of performing an APIcall 161 to a credit reporting service, which may return data concerningeach object's 130 (borrower's) creditworthiness. An implementation ofplatform 100 consistent with this example and comprising a userinterface may enable a user to configure the API call UCE 110 in amanner such as that depicted in FIG. 4.

In a non-limiting, general example of the operation a process 170, afirst UCE 110 may take in objects 130. The objects' 130 parameters 140may comprise user data and message text. The first UCE 110 may passobjects 130 to a second UCE 110 that may query a database for a phonenumber corresponding to the objects 130 (users). The second UCE may passobjects 130 (now including phone number as a parameter 140) to a thirdUCE 110 that may call an API for an SMS messaging service, instructingthe SMS messaging service to transmit the textual data to the user'sphone number. An implementation of platform 100 consistent with thisexample and comprising a user interface may enable a user to configurethese UCE 110 in a manner such as that depicted in FIGS. 2A-B, 4, and 7.

In this example, there may be UCE 110 branches performing variousfunctionality—for instance, handling error states of the various stepsalong the path. The second UCE 110 may have an error handling branch toa node 110 that handles, for example, what happens if the database querytakes too long to respond, finds the user but no phone number, or failsto find a corresponding user at all. The third UCE 110 may have an errorhandling branch to a node 110 that handles, for example, what happens ifthe API takes too long to respond, or returns an error due to anout-of-country or incorrectly formatted number.

Platform 100 may comprise a user interface for creating, managing, andinteracting with UCEs 110 and processes 170. Some features of a userinterface, as may be present in various embodiments, may follow. Onesuch feature may be foldered organization and management of processes170. Another such feature may be “drag-and-drop” (i.e. pointing devicenavigable) creation, selection (as among nodes 110 differentiated byfunction 160), interconnection, and modification of UCEs 110. Anothersuch feature may be the display of process or state “maps” thatvisualize relationships between nodes 110. In various embodiments, avisual mapping of a process 170 may comprise displaying each of theprocess' 170 UCEs 110 and each interconnection among the process' 170UCEs 110.

Another such feature may be providing templates that comprise pre-setand preconnected collections of UCEs 110. In various embodiments, suchtemplates may be presented to a user of an example interface to platform100 in the form of a template library. Another such feature may beproviding model API call nodes 110 preconfigured for connecting withparticular APIs. Another such feature may be the display of pertinentdata and inputs upon indicating (i.e. selecting) a particular element ina process 170 such as a node 110 or connection.

In an example, a user interface of platform 100 might display, uponselection of a particular node 110, pertinent parameters 140, fields forentry of pertinent data (e.g. a language selector and code or databasequery input box, URL for an API call). The user interface may alsodisplay other pertinent options for the functioning of the node 110,such as whether to send system information, whether and what to sendwith respect to header information, cryptographic signature, limitingthe time of a task 130 in the node 110, etc.

In some embodiments, a user interface of platform 100 may automaticallycreate and interconnect various nodes 110 upon the user's creation of anode 110 of a particular type. For example, upon creating a UCE 110 ofthe type “API call”, platform 100 may automatically create an errorhandling loop comprising a conditional node 110 which may operate on thetype of error (e.g. long wait for answer, failed to add parameters 140to query, invalid format provided, empty URL, response is too large,etc.). The conditional node 110 may, by its logic, pass objects 130 withsome errors to a delay node 110 (looped back to the API call node 110 toretry after a delay). This may be the case for errors that are deemed“recoverable” (e.g. long wait for answer). The conditional node 110 may,by its logic, pass other errors to a terminal exit node 110 signifyingthe process 170 was terminated in an error state. This may the case forerrors that are deemed “non-recoverable” (e.g. empty URL). Animplementation of platform 100 consistent with this example andcomprising a user interface may enable a user to configure an API callUCE 110 and a conditional UCE 110 in a manner such as that depicted inFIGS. 4 and 6.

Platform 100 may comprise analytics, dashboarding, and datavisualization functionality. In various embodiments, platform 100 mayprovide visibility into the current status of running processes 170. Forexample, platform 100 may provide metrics that may be derived fromcounters 150 or object 130 parameters 140. Examples of metrics mightinclude how many callers are currently in a call queue waiting for anoperator to speak with them, how many loan requests have been routed tovarious risk tier “buckets” (e.g. end nodes 110 to which objects 130 arerouted), or the 24 hour trend of currency exchange rates polled atregular intervals.

In various embodiments of platform 100, counters 150 as well as thestates (current parameters 140) of objects 130, of any UCE 110, may beutilized for current and historical analytics, dashboards, datavisualizations, graphical representations, etc. Such status visibilitymay, in some embodiments, be available in “realtime”. In someembodiments, “realtime” may mean there is little delay between platform100 reaching a state and the availability of that current state toanalytics/dashboarding.

Platform 100 may itself comprise one or more APIs for interacting withvarious components of platform 100. Non-limiting examples of APIinteractions with platform 100 follow. An example API to platform 100may enable the creating, duplicating, and destroying of objects 130 andthe moving objects 130 between nodes 110. An example API to platform 100may enable altering parameters 140. An example API to platform 100 mayenable altering counters 150. An example API to platform 100 may enablecreating, modifying, and deleting processes 170 (including variousaspects of processes' 170 UCEs 110). An example API to platform 100 mayenable creating, modifying, deleting, and interacting with analytics,dashboards, and data visualizations. An example API to platform 100 mayenable the performing of administrative functions (e.g. changing userpermissions).

Platform 100 and elements thereof (e.g., a process 170), may beimplemented in a storage medium such as a database, or in memory, as isdiscussed further infra Section III (see FIGS. 10-11). UCEs 110 andprocesses 170 may be combined to construct algorithms of arbitrarycomplexity; in various embodiments, platform 100 may be implemented as aTuring complete computational system, as is discussed further infraSection III (see FIGS. 13A-B).

ii. Example Implementation 200

An example implementation 200 consistent with that depicted in FIGS.2A-B includes a plurality of nodes 110 interconnected to form a process170 for authenticating users via their phone numbers. This example maybegin with a “Start” node 110 where objects 130 (representing users tobe authenticated) may enter process 170. An object 130 may proceed to a“Copy task” node 110 (labeled “1”), where it may be copied, along withrelevant parameters 140, to another process 170. In this example, theobject 130 may be copied to a “Send Message” process 170 for sending anauthentication SMS message (e.g., a 6-digit code) to the user, so thatthey may confirm their receipt of the message and thus their possessionof the relevant authenticating device.

If the communication with the “Send Message” process 170 results in anerror, an object 130 may proceed into a special error handling loop thatmay delay and retry or exit altogether in an error state. This mayreflect a specific instance of how platform 100 may, in someembodiments, enable error handling, in that nodes 110 whose functions160 that may result in error states may be provided with“conditional-like” interconnection points that may permit outflow ofobjects 130 based on the occurrence of an error state.

Otherwise, objects 130 may proceed to a “Waiting for Callback” node 110(labeled “2”) that awaits the response of the user to the authenticationmessage generated by the “Send Message” process 170. Any user responsemay proceed to the “Condition” node 110 (labeled “3”) that may providean opportunity for an exit command to be issued by the user. Such inputmay lead to a terminal “exit” node 110, canceling the process 170.Otherwise, an object 130 may proceed to another “Condition” node 110(labeled “4”) which may validate the user's response. If the userentered the wrong value, object 130 may return to the “Copy task” node110 (labeled “1”). Otherwise, upon success, object 130 may proceed toone of two “Set Parameter” nodes 110 (labeled “5.1” and “5.2”) dependinghow the platform that served as the source of the object 130 providedphone contact details. If for some reason the setting of the “phone”parameter 140 would result in an error state, each of the “SetParameter” nodes 110 has a terminal exit node 110.

An object 130 may then proceed to a “Modify Task” node 110 (labeled“6”). This node 110 may set the “phone” parameter 140 of a user dataobject 130 in a “User Profile” process 170. There may be an errorhandling loop to deal with the possibility that communication with the“User Profile” process 170 may result in an error. An object 130 maythen proceed to a “Copy task” node 110 (labeled “7”). This node 110 maycopy the object 130 (user), now authenticated, to another process 170.In this example, this may be a “Router” process 170 from which thisauthentication process 170 may have been initially called. Again, theremay be an error handling loop attached to this node 110 (for example, ifthe other process 170 is not active) but if no error is encountered, anobject 130 may then proceed to a successful “END” node 110.

It may be noted that, in various embodiments, each of the nodes 110 in aprocess 170 such as that depicted in example implementation 200 may betrackable in a dashboard or otherwise available as a source of analyticsdata. For example, a dashboard may track a counter 150 of how many usersissued an exit command before reaching a successful conclusion (objects130 that reach the exit node 110 of the “Condition” node 110 labeled“3”), how many users there are currently waiting for a response to the“Send Message” process 170 (objects 130 in the queue 120 of the “Waitingfor Callback” node 110 labeled “2”), how many users successfullyauthenticated (objects 130 that reach the “END” exit node 110 of the“Copy task” node 110 labeled “7”), etc.

Further discussion of features platform 100 may comprise follows.

b. Universal Computing Element 110 and Process 170

Platform 100 may comprise a universal computing element 110. A UCE 110may comprise a queue 120 of objects 130 characterized by parameters 140,counters 150 that may store data about queue 120 or objects 130, and afunction 160 that may operate on parameters 140 or counters 150.

In some embodiments, UCEs 110, as presented to users in an interface toplatform 100, may be specialized so as to, for example, simplify andguide the user experience. Such specialization may, for instance,comprise specialized function 160 functionality that presents particular“types” of nodes 110 (discussed further infra) such as conditional nodes110, API call nodes 110, delay nodes 110, wait for response nodes 110,etc., each of which may be a subset of the generalized power of function160 to operate upon parameters 140 and counters 150.

Inputs of objects 130 to a process 170 (and generally to a UCE 110) maycome from multiple sources. For example, 4 different APIs 131 and amanual data entry source 132 may all feed the start node 110 of a singleprocess 170. In various embodiments, one or multiple processes 170 mayhave a node 110 whose function 170 b calls on a (sub-) process 170 toperform some subset of processing. As an example, such a “calling”process 170 may act as a source 170 a of (i.e. “passing in” of) objects130 to the (sub-) process 170.

UCEs 110 may have between zero (i.e. an end node 110) and arbitrarilymany outbound paths to other UCEs 110. Multiple UCEs 110 may haveoutbound interconnections to a single inbound (i.e. receiving) UCE 110.UCEs 110 can be connected linearly or in complex looping, branching,etc. configurations. Platform 100 may comprise protections againstinfinite loops, for example a rule that stops processing if a task 130would be cycled over 50 times through a loop of nodes 110.

In various embodiments, one or more end nodes 110 may serve as theterminal points of a process 170. By way of non-limiting example, an endnode 110 may have zero outbound interconnections to other UCEs 110.Consistent with such an example, objects 130 that reach (the queue 120of) an end node 110 may not proceed to any other nodes 110, but rathermay be “collected” in the end node's 110 queue 120. In some embodimentsnot inconsistent with such an example, an object 130 reaching an endnode 110 may trigger an action by the platform 100, such as issuing analert, creating a new object 130, or invoking another process 170.

In some embodiments, one or more counters 150 may track objects 130 thatreach an end node 110. In an example, an end node 110 may have a counter150 that tracks the number of objects 130 in that end node's 110 queue120. In another example, an end node 110 may have a counter 150 thattracks the time of entry of each object 130 to that end node's 110 queue120.

Processes 170 may have the ability (e.g., through a user interfaceselection) to be in different states of activity. Different states ofactivity may comprise, but not be limited to, an active state (i.e.,actively running and processing objects 130), a paused (i.e. notrunning) state, or debug state (which may permit additional developmentactivities in the running of processes 170 such as setting breakpoints).A process 170 in a paused state may cause an error state in anotherprocess 170 that calls it or otherwise depends on it being in activeoperation. This may make it opportune for some embodiments to comprise auser interface to platform 100 that automatically creates error handlingloops for functions 160 like calling another process 170.

c. Queue 120, Object 130, and Parameters 140

Platform 100 may comprise a queue 120 of one or more objects 130. Anobject 130 may comprise data in the form of parameters 140 thatcharacterize object 130. Object 130 may be devoid of parameters 140(i.e., a pure “pulse” to be run through the process 170). A queue 120may store an arbitrary number of objects 130.

While objects 130 in a queue 120 may correspond to ordering information(e.g., a timestamp counter 150 sequentializing the entry of objects 130into the queue 120), a queue 120 need not be conceptualized as asequential first in first out (FIFO) or last in first out (LIFO) datastructure. Objects 130 are susceptible to infinitely many categorizingcriteria based on their parameters 140 and various counters 150. Thiscategorizing principle may be used to distribute objects 130 amongstUCEs 110 (recall that an object can pass to one of potentially many UCEs110 b) in ways that do not depend on the time sequence of entry of theobjects 130 into the queue 120.

In some embodiments, some parameters 140 may be “global” in the sensethat these parameters 140 are available as to all objects 130 at alltimes. Such globally available parameters 140 may include a timestamp ofthe object's 130 creation (i.e., when it first became an object in thisprocess 170), the last time the object 130 changed state (i.e., changein a parameter 140), various static and dynamic timer values, the ID ofthe current node 110 where the object 130 is queued, and the ID of theobject 130 itself.

Parameters 140 may comprise any type of data, from strings, numbers, andbooleans, to geographic coordinates, JavaScript Object Notation (JSON)data, images, binary data, pointers, etc. Not all objects 130 in aprocess 170 or in a queue 120 are required to have the same datastructure (i.e. set of parameters 140 and data types for their values).Since inputs of objects 130 to a process 170 or UCE 110 may come fromdifferent sources, various sources may name, type, structure, include,or omit parameters 140 in their own idiosyncratic ways. For example,while one bank's API may return a field (parameter 140) titled“blacklisted” with a value of “TRUE”, another's may return the field“black_listed” with a value of “yes”, and another's may not return thefield at all.

In some senses, “events” can be conceptualized as drivers behind changesin state of objects 130. One example of such driver may include a firstcredit card transaction acting as a trigger for processes 170 to changea parameter 140 of an object 130 representing the credit card holderfrom a state (parameter 140 value) of “inactive” to “active”. In keepingwith this conceptualization, the absence of an “event” can itself be anevent. By way of some non-limiting examples: a credit card holder going60 days without a credit card transaction, or an online shopper going 24hours with items in a checkout “basket” without clicking the “check out”button, may be the “event” upon which platform 100 takes action.

d. Counter 150

Platform 100 may comprise a counter 150. Counters 150 may storeinformation about queue 120 or object 130. For example, a counter 150may store information about the number of objects 130 in queue 120. Foranother example, a counter 150 may store the timestamp of each object's130 entrance into queue 120. Counter 150 may store other information(i.e. “custom counters”) about objects 130 in the queue 120. By way ofsome non-limiting examples of counters 150: how many objects 130representing callers have a parameter 140 of “VIP” set to “TRUE”, howmany objects 130 representing potential loan customers do not contain aparameter 140 of “credit score”, or how many objects 130 representinginternet of things (IOT) devices fall within a particular geographicregion.

Counters 150 may be utilized by processes 170 to set limits according tobusiness logic. For example, a counter 150 of the queue 120 of activechats with a customer service agent may be utilized to triage awayadditional incoming chat instances (objects 130) once the queue 120reaches 10. This could service the business logic “agents are allowed tochat with a maximum of 10 customers at one time.” For another example, acounter 150 of the timestamps of entry of tasks 130 into the queue 120of a node 110 signifying a caller ready to be connected with an operatormay be utilized to calculate the time since entry. This could beutilized in implementing the business logic “no caller (who reaches thispoint in the call system) should wait more than 30 seconds to speak witha human.”

e. Function 160

Platform 100 may comprise a function 160. A node's 110 function 160 mayoperate on a counter 150 or on a parameter 140 of an object 130 in thequeue 120 of that node 110. Functions 160 may be categorized in variousways; examples of functions 160 include calls to APIs 161 and toexternal (or internal) systems and interfaces in general, calls formanual input 162, calls to other processes 170 b (which may include aprocess 170 calling itself), execution of code 163, calls to databases164, system actions 165. System actions 165 may comprise such actions asapplying a conditional (e.g. comparison operators, logical operators,bitwise operators, regular expressions, etc.), waiting for a response,delaying further processing, error handling, setting a parameter 140,establishing a queue 120 for another process 170 to process, performingmathematical operations, employing a source of randomness (e.g. ahardware or software random number generator), setting a state, andissuing a notification. General UCE 110 functions 160 may comprisecounter functions 166 that operate on counters 150. Counter functions166 may be based upon such counter 150 values as the number of objects130 in queue 120, the timestamp of objects' 130 entry into queue 120, orother counters 150. There may be overlap between variouscategorizations, especially with the relatively encompassing function160 of executing code 163.

Some depictions of example interfaces to platform 100, showing exampleimplementations of various functions 160, follow. FIG. 3 depicts anexample interface to platform 100 showing example implementation 300. Inexample implementation 300, an interface 310 may present a “menu” ofavailable types of node 110. In an example user interface to platform100 consistent with that depicted in FIG. 3, a user may, uponinteracting with (e.g. mousing over, clicking) an interconnectionbetween a first and a second node 110, be presented with an interfacefor creating a new node 110 interposed between the extant interconnectednodes 110. Such an interface may present the user with a “menu” ofavailable types of nodes 110 (i.e. UCEs 110 classified by the type ofpredetermined function 160 with which they are to be created). Upon theuser's selection of a particular type of node 110 from the “menu”,platform 100 may create a new node 110 interposed between the two extantnodes 110—that is, the new node 110 may be a recipient of aninterconnection from the first node and the originator of aninterconnection to the second node 110.

FIG. 4 depicts an example interface to platform 100 showing exampleimplementation 400. In example implementation 400, an API call node 410is shown. A node 110 whose function 160 is an API call may be configuredto communicate with an external system (which term may include anapplication programming interface to platform 100 itself) in astructured way. This structure may be reflected in data and inputspresented to a user upon selecting in a user interface to platform 100of an API call node 110, such as that depicted in FIG. 4. An API callmay utilize a URL so that it may communicate with the external system,URL string parameters that may be included in the URL request string, anHTTP request method, etc. The various inputs to this example API callmay be presented to a user in a user interface of platform 100.

In an example consistent with example implementation 400 as depicted inFIG. 4, a user may be provided appropriate inputs for the API call. Suchinputs may include the API URL (e.g. a text box), request method (e.g. adropdown selector providing choices such as “GET” and “POST”), URLstring parameters (e.g. text boxes arranged as “name: value” pairs whichmay permit the selection of extant object 130 parameters 140), andadditional settings for the API call (such as limiting the number ofsimultaneous requests to the API, header data, etc.).

Upon making an API call, the external system may apply its rules to thesubmitted query and take action thereupon. For example, the externalsystem may return JSON formatted data to platform 100. An API call node110 may receive the external system's response. The node 110 may utilizethe external system's response by, for example, setting parameters 140(of the object 130 that precipitated the API call) in accordancetherewith. In an example, a call to a stock value API may return adollar value and an associated timestamp. In this example, upon receipt,the calling node 110 may set parameters 140 of the object 130—alreadyequipped with a value for “stock_ticker_symbol” but blank in theparameters 140 “value” and “value_timestamp”—to the returned values.

As with various types of node 110, a UCE 110 specialized to make APIcalls may, upon creation, be automatically provided by platform 100 withan error handling loop. Such an error handling loop may comprise abuilt-in conditional to route errors out of the API call node's 110queue 120, a conditional node 110 to handle the type of error generated,one or more exit nodes 110, and a “retry” delay node 110 interconnectingback to the API call node 110.

FIG. 5 depicts an example interface to platform 100 showing exampleimplementation 500. In example implementation 500, a code execution node510 is shown. In some senses, code execution may be conceptualized as aspecialization, in that, in a particular implementation of platform 100,only certain programming languages and functionality may be madeavailable to a user. In some senses, code execution may beconceptualized as a more generalized case of function 160 types, in thatother specializations (calling an API, calling a code versioningrepository, delaying, applying conditional logic, etc.) couldtheoretically be performed by the execution of arbitrary code. Invarious embodiments, platform 100 may expose variables such asparameters 140 to code execution nodes 110. For example, an object's 130parameter 140 “parameter_name” may be made available to a code executionnode 110 as “data.parameter_name”.

FIG. 6 depicts an example interface to platform 100 showing exampleimplementation 600. In example implementation 600, a conditional node610 is shown. In various embodiments, a conditional node 110 may have anarbitrary number of conditions, each providing an originatinginterconnection point outbound to a node 110. In various embodiments,conditions may operate on object 130 parameters 140 (e.g. “IF vip==TRUE. . . ”), on states resulting from lack of an object 130 (e.g.“IF_error==no_object”), on counters 150 (e.g. “IF c_t>30”), orcombinations of the aforementioned.

In some embodiments, conditional nodes 110 may make only certainoperators available in certain combinations. In an example, conditionalnodes 110 may make only equality, inequality, greater than, less than,and regular expression matching available as conditions, andcombinations of conditions only by AND OR logical operators. Differentimplementations of platform 100 may make available to conditional nodes110 different subsets of the universe of comparison operators, logicaloperators, bitwise operators, regular expressions, etc.

FIG. 7 depicts an example interface to platform 100 showing exampleimplementation 700. In example implementation 700, wherein a databasecall node 710 is shown. In an example, platform 100 may have aninterface for setting up a database connection. In further consistentembodiments, a database call node 110 may reference a databaseconnection. A user interface to platform 100 may provide an input fieldfor making an actual query to the database in a language such asStructured Query Language (SQL), GraphQL, MongoDB Query Language (MQL),etc.

f. Analytics, Data Visualization, and Dashboard

Platform 100 may comprise analytics, data visualization, and dashboardfunctionality. In various embodiments, such functionality may berealtime as well as historical. In various embodiments, suchfunctionality may be based on metrics (i.e. states of counters 150 andparameters 140) from any UCE 110. For example, a metric may correspondto a counter 150 of the number of objects 130 that have reached asuccessful end node 110 of a process 170. For another example, a metricmay be based on a counter 150 of the number of objects 130 in a queue120 of a particular node 110 having a parameter 140 that meets aparticular criteria (“is_vip” is TRUE, “times_contacted” is less than orequal to 3, etc.).

In various embodiments, a dashboard may be capable of displaying metricsfrom multiple processes 170. In various embodiments, a dashboard may becapable of displaying different time ranges. Time ranges may includeexamples such as realtime, past 10 minutes, past hour, past 24 hours,past week, past year, and custom user-specified ranges. In furtherconsistent embodiments, a dashboard may display metrics over those timeranges. By way of some non-limiting examples, a dashboard may displaysuch metrics as: successful process 170 completions over the past 24hours, current (realtime) number of users in the queue 120 of aparticular node 110, process 170 failures due to API call errors over aparticular two week period, etc.

In various embodiments, data visualizations of a dashboard may beavailable. Such data visualizations may include examples such as barcharts, pie charts, funnel charts, etc. Data visualizations maycomprise, by way of some non-limiting examples: maps of processes 170that display realtime or historical data about activity in various nodes110, charts of the activity in interconnected processes 170, geographicvisualizations (e.g. maps of where objects 130 are originating from,charts that show errors at a particular node 110 by country), heat maps,scatter plots, bubble charts, etc.

An example interface to platform 100, implementing analytics, datavisualization, and dashboard functionality, is depicted in FIGS. 8A-C.FIG. 8A depicts an example interface to platform 100 showing exampleimplementation 800, wherein a selection (for inclusion in a dashboard)of metrics is presented for nodes 810 of processes 870. FIG. 8B depictsan example interface to platform 100 showing example implementation 800,wherein dashboard 820 (including chosen metrics from nodes 810) isshown. FIG. 8C depicts an example interface to platform 100 showingexample implementation 800, wherein a data visualization 830 ofdashboard 820 is shown. While each of the metrics selected in exampleimplementation 800 are from a single process 170, entitled “Tracking”,other processes 170 may have been included on the dashboard and relateddata visualization. For example, the process 170 “Packages (cities)”seen under processes 870 on FIG. 8A may have been chosen as a source ofmetrics.

II. METHOD OF USE

Referring now to FIGS. 9A-C, there is shown an example method 900 ofutilizing platform 100 to process inbound customer calls. FIG. 9Adepicts the entire process in a flowchart diagram, including twosubprocesses 910 and 950 of method 900. FIG. 9B depicts an exampleinterface to platform 100 showing the implementation of subprocess 910(or the “calls queue”). Example subprocess 910 may comprise a process170 which may be responsible for maintaining the queue of customer calls(i.e. tracking changes in the state of calls). FIG. 9C depicts anexample interface to platform 100 showing the implementation ofsubprocess 950 (or the “operator queue”). Example subprocess 950 maycomprise a process 170 which may be responsible for processing of callsby an operator. Note that the term “queue” as used in “calls queue 910”and “operator queue 950” is in the general sense of processing callers,and not the queue 120 of an individual UCE 110.

g. Subprocess 910 (the “Calls Queue”)

Method 900 may begin with a new customer call at stage 911, which maycomprise the start node 110 of the calls queue 910. The customer callmay be represented by an object 130. Object 130 may proceed to stage912, which may comprise a node 110 that establishes a queue 120 for useby another process 170. In this example, at stage 912, a new customercall object 130 may be placed into a new customer call queue 120 for useby the operator queue 950. Subprocess 910 may wait for a response fromthe operator queue 950 (the result of attempting to communicate with thecustomer) at stage 913.

Stage 914 may comprise a conditional node 110. In this example, theconditional node 110 may apply the following logic: if the result fromthe operator queue 950 was a successful communication with the customer,object 130 may proceed to stage 915, which may be an end node 110 ofsubprocess 910 indicating successful communication. If the result fromoperator queue 950 was not a successful communication, object 130 mayproceed to stage 916. Stage 916 may comprise a delay node 110 that holdsobject 130 for 3 hours before proceeding to stage 917.

Stage 917 may comprise a node 110 that establishes a queue 120 for useby another process 170. In this example, at stage 917, object 130 may beplaced into a customer re-call queue 120 for use by the operator queue950. Subprocess 910 may wait for a response from the operator queue 950(the result of attempting to communicate with the customer) at stage918.

Stage 919 may comprise a conditional node 110. In this example, theconditional node 110 may apply the following logic: if the result fromthe operator queue 950 was a successful communication with the customeron the re-call, object 130 may proceed to stage 915, which may be an endnode 110 of subprocess 910 indicating successful communication. If theresult from operator queue 950 was nota successful communication, object130 may proceed to stage 920.

Stage 920 may comprise a conditional node 110. In this example, theconditional node 110 may apply the following logic: if object 130 has acall count parameter 140 indicating this was the third attempt to reachthe customer, object may proceed to stage 921, which may be an end node110 of subprocess 910 indicating communications were closed after 3unsuccessful attempts. If object 130 does not have a call countparameter 140 indicating this was the third attempt to reach thecustomer, object 130 may proceed to a “Set Parameter” node 110 that setsthe call count parameter 140 and on to stage 922 which may comprise thesame delay node 110 as stage 916. Object 130 may then proceed (i.e. loopback) to stage 917 to the node 110 that, in this example, establishesthe customer re-call queue 120 for use by subprocess 950.

h. Subprocess 950 (the “Operator Queue”)

Meanwhile, subprocess 950 may begin at stage 951, which may comprise thestart node 110 of the operator queue 950. Stage 952 may comprise a node110 that attempts to get an object 130 from the (in this example, higherpriority) customer re-call queue 120 populated at stage 917.

Stage 953 may comprise a conditional node 110. In this example, theconditional node 110 may apply the following logic: if the result ofstage 952 is that no objects 130 are received (i.e. the customer re-callqueue 120 is empty), method 900 may proceed to stage 954. Stage 954 maycomprise a node 110 that attempts to get an object 130 from the (in thisexample, lower priority) new customer call queue 120 populated at stage912.

Stage 955, may comprise a conditional node 110. In this example, theconditional node 110 may apply the following logic: if the result ofstage 954 is that no objects 130 are received (i.e. the new customercall queue 120 is empty), method 900 may proceed to stage 956, which maybe an end node 110 of subprocess 950 indicating there are no customersto contact.

If the result of either stage 954 or stage 952 is that an object 130 isreceived, object 130 may proceed (from stage 955 or stage 953,respectively) to stage 957. Stage 957 may comprise a node 110 which maysend the object (“task”) 130 to an operator to initiate communication.Subprocess 950 may await the results of that communication (e.g.successful or unsuccessful) at stage 958. Object 130 may proceed tostage 959. Stage 959 may comprise a “Modify Task” node 110 that utilizesthe result of the communication (e.g. successful or unsuccessful) toupdate an object 130 in subprocess 910 waiting at either stage 913 orstage 918 for a response from the operator queue 950 (for new calls fromstage 954 or re-calls from stage 952, respectively). Subprocess 950 mayconclude with an end node 110 at stage 960.

The order of stages presented are only illustrative of the possibilitiesand those steps can be executed or performed in any suitable fashion.Moreover, the various features of the examples described here are notmutually exclusive. Rather any feature of any example described here canbe incorporated into any other suitable example. It is intended that thespecification and examples be considered as exemplary only, with a truescope and spirit of the invention being indicated by the followingclaims.

III. PLATFORM ARCHITECTURE

i. Architectural Implementations

FIG. 10 depicts a general architectural overview of an exampleimplementation 1000 of platform 100. Example implementation 1000 mayinclude API applications (including acceptance of requests, processmanagement, managing state diagrams, etc.), counters 150, cache (i.e.memory), main logic applications (including most specialized UCE 110functionality), HTTP applications (including outgoing API requests),user's code applications (including compilation and execution ofarbitrary code as functions 160), the message queue (labeled “MQ”), anddatabase (representing a storage medium in which platform 100 may beimplemented).

FIG. 11 depicts a general architectural overview of an exampleimplementation 1100 of platform 100. Example implementation 1100 maylargely mirror example implementation 1000 as depicted in FIG. 10, witha key difference being this example system's 100 implementation inmemory versus in a storage medium (compare positions of “Cache” and“Database” in FIG. 10 with positions of “DB”, which stands for“database”, and “Cache” in FIG. 11). Implementation of platform 100 inmemory may have desirable effects such as enhanced efficiency and fasterlaunch speed.

FIG. 12 depicts a simplified activity diagram of the interpretationalgorithm 1200 that may run at each node 110 in an exampleimplementation of platform 100. In various embodiments, the manner inwhich UCEs 110 may implement functions 160, check counters 150, andprocess objects 130 may be conceptualized in accordance with thesimplified activity diagram of FIG. 12. The diagram is simplified in atleast the following ways: not all erroneous situations and errorhandling points are depicted, not all functions 160 are depicted,details related to the transformation of data formats in theorganization of external API calls are not depicted, the features ofoperation in start and end nodes 110 are not depicted, not all object130 routing is depicted, etc.

An example implementation 1300 of platform 100 demonstrating Turingcompleteness is presented in FIGS. 13A-B. FIG. 13A depicts a blockdiagram of example implementation 1300, while FIG. 13B depicts anexample interface to platform 100 showing example implementation 1300.

j. System Implementations

Embodiments of platform 100 may comprise aspects including, but notlimited to, mobile software applications (or “apps”), websites, webapplications, desktop software, server software, embedded software,microcontrollers, databases, wired and wireless networking hardware andsoftware, and various computing devices. Moreover, platform 100 oraspects thereof may be hosted one or more physical or virtual servers,cloud computing services, blockchain platforms, or distributed computingplatforms. Alternatively, or in addition, platform 100 may beimplemented in one or more of a plurality of computing devices.

Embodiments of the present disclosure may comprise a system having acentral processing unit (CPU) 1420, a bus 1430, a memory unit 1440, apower supply unit (PSU) 1450, and one or more Input/Output (I/O) units.The CPU 1420 coupled to the memory unit 1440 and the plurality of I/Ounits 1460 via the bus 1430, all of which are powered by the PSU 1450.It should be understood that, in some embodiments, each disclosed unitmay actually be a plurality of such units for the purposes ofredundancy, high availability, and/or performance. The combination ofthe presently disclosed units is configured to perform the stages anymethod disclosed herein.

FIG. 14 is a block diagram of a system including computing device 1400.Consistent with an embodiment of the disclosure, the aforementioned CPU1420, the bus 1430, the memory unit 1440, a PSU 1450, and the pluralityof I/O units 1460 may be implemented in a computing device, such ascomputing device 1400 of FIG. 14. Any suitable combination of hardware,software, or firmware may be used to implement the aforementioned units.For example, the CPU 1420, the bus 1430, and the memory unit 1440 may beimplemented with computing device 1400 or any of other computing devices1400, in combination with computing device 1400. The aforementionedsystem, device, and components are examples and other systems, devices,and components may comprise the aforementioned CPU 1420, the bus 1430,the memory unit 1440, consistent with embodiments of the disclosure.

At least one computing device 1400 may be embodied as any of thecomputing elements illustrated in all of the attached figures. Acomputing device 1400 does not need to be electronic, nor even have aCPU 1420, nor bus 1430, nor memory unit 1440. The definition of thecomputing device 1400 to a person having ordinary skill in the art is “Adevice that computes, especially a programmable electronic machine thatperforms high-speed mathematical or logical operations or thatassembles, stores, correlates, or otherwise processes information.” Anydevice which processes information qualifies as a computing device 1400,especially if the processing is purposeful.

With reference to FIG. 14, a system consistent with an embodiment of thedisclosure may include a computing device, such as computing device1400. In a basic configuration, computing device 1400 may include atleast one clock module 1410, at least one CPU 1420, at least one bus1430, and at least one memory unit 1440, at least one PSU 1450, and atleast one I/O 1460 module, wherein I/O module may be comprised of, butnot limited to a non-volatile storage sub-module 1461, a communicationsub-module 1462, a sensors sub-module 1463, and a peripherals sub-module1464.

A system consistent with an embodiment of the disclosure the computingdevice 1400 may include the clock module 1410 may be known to a personhaving ordinary skill in the art as a clock generator, which producesclock signals. Clock signal is a particular type of signal thatoscillates between a high and a low state and is used like a metronometo coordinate actions of digital circuits. Most integrated circuits(ICs) of sufficient complexity use a clock signal in order tosynchronize different parts of the circuit, cycling at a rate slowerthan the worst-case internal propagation delays. The preeminent exampleof the aforementioned integrated circuit is the CPU 1420, the centralcomponent of modern computers, which relies on a clock. The onlyexceptions are asynchronous circuits such as asynchronous CPUs. Theclock 1410 can comprise a plurality of embodiments, such as, but notlimited to, single-phase clock which transmits all clock signals oneffectively 1 wire, two-phase clock which distributes clock signals ontwo wires, each with non-overlapping pulses, and four-phase clock whichdistributes clock signals on 4 wires.

Many computing devices 1400 use a “clock multiplier” which multiplies alower frequency external clock to the appropriate clock rate of the CPU1420. This may allow the CPU 1420 to operate at a much higher frequencythan the rest of the computer, which affords performance gains insituations where the CPU 1420 does not need to wait on an externalfactor (like memory 1440 or input/output 1460). Some embodiments of theclock 1410 may include dynamic frequency change, where, the time betweenclock edges can vary widely from one edge to the next and back again.

A system consistent with an embodiment of the disclosure the computingdevice 1400 may include the CPU unit 1420 comprising at least one CPUCore 1421. A plurality of CPU cores 1421 may comprise identical CPUcores 1421, such as, but not limited to, homogeneous multi-core systems.It is also possible for the plurality of CPU cores 1421 to comprisedifferent CPU cores 1421, such as, but not limited to, heterogeneousmulti-core systems, big.LITTLE systems and some AMD acceleratedprocessing units (APU). The CPU unit 1420 reads and executes programinstructions which may be used across many application domains, forexample, but not limited to, general purpose computing, embeddedcomputing, network computing, digital signal processing (DSP), andgraphics processing (GPU). The CPU unit 1420 may run multipleinstructions on separate CPU cores 1421 at the same time. The CPU unit1420 may be integrated into at least one of a single integrated circuitdie and multiple dies in a single chip package. The single integratedcircuit die and multiple dies in a single chip package may contain aplurality of other aspects of the computing device 1400, for example,but not limited to, the clock 1410, the CPU 1420, the bus 1430, thememory 1440, and I/O 1460.

The CPU unit 1420 may contain cache 1422 such as, but not limited to, alevel 1 cache, level 2 cache, level 3 cache or combination thereof. Theaforementioned cache 1422 may or may not be shared amongst a pluralityof CPU cores 1421. The cache 1422 sharing comprises at least one ofmessage passing and inter-core communication methods may be used for theat least one CPU Core 1421 to communicate with the cache 1422. Theinter-core communication methods may comprise, but not limited to, bus,ring, two-dimensional mesh, and crossbar. The aforementioned CPU unit1420 may employ symmetric multiprocessing (SMP) design.

The plurality of the aforementioned CPU cores 1421 may comprise softmicroprocessor cores on a single field programmable gate array (FPGA),such as semiconductor intellectual property cores (IP Core). Theplurality of CPU cores 1421 architecture may be based on at least oneof, but not limited to, Complex instruction set computing (CISC), Zeroinstruction set computing (ZISC), and Reduced instruction set computing(RISC). At least one of the performance-enhancing methods may beemployed by the plurality of the CPU cores 1421, for example, but notlimited to Instruction-level parallelism (ILP) such as, but not limitedto, superscalar pipelining, and Thread-level parallelism (TLP).

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ a communication systemthat transfers data between components inside the aforementionedcomputing device 1400, and/or the plurality of computing devices 1400.The aforementioned communication system will be known to a person havingordinary skill in the art as a bus 1430. The bus 1430 may embodyinternal and/or external plurality of hardware and software components,for example, but not limited to a wire, optical fiber, communicationprotocols, and any physical arrangement that provides the same logicalfunction as a parallel electrical bus. The bus 1430 may comprise atleast one of, but not limited to a parallel bus, wherein the parallelbus carry data words in parallel on multiple wires, and a serial bus,wherein the serial bus carry data in bit-serial form. The bus 1430 mayembody a plurality of topologies, for example, but not limited to, amultidrop/electrical parallel topology, a daisy chain topology, and aconnected by switched hubs, such as USB bus. The bus 1430 may comprise aplurality of embodiments, for example, but not limited to:

-   -   Internal data bus (data bus) 1431/Memory bus    -   Control bus 1432    -   Address bus 1433    -   System Management Bus (SMBus)    -   Front-Side-Bus (FSB)    -   External Bus Interface (EBI)    -   Local bus    -   Expansion bus    -   Lightning bus    -   Controller Area Network (CAN bus)    -   Camera Link    -   ExpressCard    -   Advanced Technology management Attachment (ATA), including        embodiments and derivatives such as, but not limited to,        Integrated Drive Electronics (IDE)/Enhanced IDE (EIDE), ATA        Packet Interface (ATAPI), Ultra-Direct Memory Access (UDMA),        Ultra ATA (UATA)/Parallel ATA (PATA)/Serial ATA (SATA),        CompactFlash (CF) interface, Consumer Electronics ATA        (CE-ATA)/Fiber Attached Technology Adapted (FATA), Advanced Host        Controller Interface (AHCI), SATA Express (SATAe)/External SATA        (eSATA), including the powered embodiment eSATAp/Mini-SATA        (mSATA), and Next Generation Form Factor (NGFF)/M.2.    -   Small Computer System Interface (SCSI)/Serial Attached SCSI        (SAS)    -   HyperTransport    -   InfiniBand    -   RapidIO    -   Mobile Industry Processor Interface (MIPI)    -   Coherent Processor Interface (CAPI)    -   Plug-n-play    -   1-Wire    -   Peripheral Component Interconnect (PCI), including embodiments        such as, but not limited to, Accelerated Graphics Port (AGP),        Peripheral Component Interconnect eXtended (PCI-X), Peripheral        Component Interconnect Express (PCI-e) (e.g., PCI Express Mini        Card, PCI Express M.2 [Mini PCIe v2], PCI Express External        Cabling [ePCIe], and PCI Express OCuLink [Optical Copper{Cu}        Link]), Express Card, AdvancedTCA, AMC, Universal 10,        Thunderbolt/Mini DisplayPort, Mobile PCIe (M-PCIe), U.2, and        Non-Volatile Memory Express (NVMe)/Non-Volatile Memory Host        Controller Interface Specification (NVMHCIS).    -   Industry Standard Architecture (ISA), including embodiments such        as, but not limited to Extended ISA (EISA),        PC/XT-bus/PC/AT-bus/PC/104 bus (e.g., PC/104-Plus,        PCI/104-Express, PCI/104, and PCI-104), and Low Pin Count (LPC).    -   Music Instrument Digital Interface (MIDI)    -   Universal Serial Bus (USB), including embodiments such as, but        not limited to, Media Transfer Protocol (MTP)/Mobile        High-Definition Link (MHL), Device Firmware Upgrade (DFU),        wireless USB, InterChip USB, IEEE 1394 Interface/Firewire,        Thunderbolt, and eXtensible Host Controller Interface (xHCI).

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ hardware integratedcircuits that store information for immediate use in the computingdevice 1400, know to the person having ordinary skill in the art asprimary storage or memory 1440. The memory 1440 operates at high speed,distinguishing it from the non-volatile storage sub-module 1461, whichmay be referred to as secondary or tertiary storage, which providesslow-to-access information but offers higher capacities at lower cost.The contents contained in memory 1440, may be transferred to secondarystorage via techniques such as, but not limited to, virtual memory andswap. The memory 1440 may be associated with addressable semiconductormemory, such as integrated circuits consisting of silicon-basedtransistors, used for example as primary storage but also other purposesin the computing device 1400. The memory 1440 may comprise a pluralityof embodiments, such as, but not limited to volatile memory,non-volatile memory, and semi-volatile memory. It should be understoodby a person having ordinary skill in the art that the ensuing arenon-limiting examples of the aforementioned memory:

-   -   Volatile memory which requires power to maintain stored        information, for example, but not limited to, Dynamic        Random-Access Memory (DRAM) 1441, Static Random-Access Memory        (SRAM) 1442, CPU Cache memory 1425, Advanced Random-Access        Memory (A-RAM), and other types of primary storage such as        Random-Access Memory (RAM).    -   Non-volatile memory which can retain stored information even        after power is removed, for example, but not limited to,        Read-Only Memory (ROM) 1443, Programmable ROM (PROM) 1444,        Erasable PROM (EPROM) 1445, Electrically Erasable PROM (EEPROM)        1446 (e.g., flash memory and Electrically Alterable PROM        [EAPROM]), Mask ROM (MROM), One Time Programable (OTP) ROM/Write        Once Read Many (WORM), Ferroelectric RAM (FeRAM), Parallel        Random-Access Machine (PRAM), Split-Transfer Torque RAM        (STT-RAM), Silicon Oxime Nitride Oxide Silicon (SONOS),        Resistive RAM (RRAM), Nano RAM (NRAM), 3D XPoint, Domain-Wall        Memory (DWM), and millipede memory.    -   Semi-volatile memory which may have some limited non-volatile        duration after power is removed but loses data after said        duration has passed. Semi-volatile memory provides high        performance, durability, and other valuable characteristics        typically associated with volatile memory, while providing some        benefits of true non-volatile memory. The semi-volatile memory        may comprise volatile and non-volatile memory and/or volatile        memory with battery to provide power after power is removed. The        semi-volatile memory may comprise, but not limited to        spin-transfer torque RAM (STT-RAM).

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ the communication systembetween an information processing system, such as the computing device1400, and the outside world, for example, but not limited to, human,environment, and another computing device 1400. The aforementionedcommunication system will be known to a person having ordinary skill inthe art as I/O 1460. The I/O module 1460 regulates a plurality of inputsand outputs with regard to the computing device 1400, wherein the inputsare a plurality of signals and data received by the computing device1400, and the outputs are the plurality of signals and data sent fromthe computing device 1400. The I/O module 1460 interfaces a plurality ofhardware, such as, but not limited to, non-volatile storage 1461,communication devices 1462, sensors 1463, and peripherals 1464. Theplurality of hardware is used by the at least one of, but not limitedto, human, environment, and another computing device 1400 to communicatewith the present computing device 1400. The I/O module 1460 may comprisea plurality of forms, for example, but not limited to channel I/O, portmapped I/O, asynchronous I/O, and Direct Memory Access (DMA).

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ the non-volatile storagesub-module 1461, which may be referred to by a person having ordinaryskill in the art as one of secondary storage, external memory, tertiarystorage, off-line storage, and auxiliary storage. The non-volatilestorage sub-module 1461 may not be accessed directly by the CPU 1420without using intermediate area in the memory 1440. The non-volatilestorage sub-module 1461 does not lose data when power is removed and maybe two orders of magnitude less costly than storage used in memorymodule, at the expense of speed and latency. The non-volatile storagesub-module 1461 may comprise a plurality of forms, such as, but notlimited to, Direct Attached Storage (DAS), Network Attached Storage(NAS), Storage Area Network (SAN), nearline storage, Massive Array ofIdle Disks (MAID), Redundant Array of Independent Disks (RAID), devicemirroring, off-line storage, and robotic storage. The non-volatilestorage sub-module (1461) may comprise a plurality of embodiments, suchas, but not limited to:

-   -   Optical storage, for example, but not limited to, Compact        Disk (CD) (CD-ROM/CD-R/CD-RW), Digital Versatile Disk (DVD)        (DVD-ROM/DVD-R/DVD+R/DVD-RW/DVD+RW/DVD±RW/DVD+R        DL/DVD-RAM/HD-DVD), Blu-ray Disk (BD) (BD-ROM/BD-R/BD-RE/BD-R        DL/BD-RE DL), and Ultra-Density Optical (UDO).    -   Semiconductor storage, for example, but not limited to, flash        memory, such as, but not limited to, USB flash drive, Memory        card, Subscriber Identity Module (SIM) card, Secure Digital (SD)        card, Smart Card, CompactFlash (CF) card, Solid-State Drive        (SSD) and memristor.    -   Magnetic storage such as, but not limited to, Hard Disk Drive        (HDD), tape drive, carousel memory, and Card Random-Access        Memory (CRAM).    -   Phase-change memory    -   Holographic data storage such as Holographic Versatile Disk        (HVD)    -   Molecular Memory    -   Deoxyribonucleic Acid (DNA) digital data storage

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ the communicationsub-module 1462 as a subset of the I/O 1460, which may be referred to bya person having ordinary skill in the art as at least one of, but notlimited to, computer network, data network, and network. The networkallows computing devices 1400 to exchange data using connections, whichmay be known to a person having ordinary skill in the art as data links,between network nodes. The nodes comprise network computer devices 1400that originate, route, and terminate data. The nodes are identified bynetwork addresses and can include a plurality of hosts consistent withthe embodiments of a computing device 1400. The aforementionedembodiments include, but not limited to personal computers, phones,servers, drones, and networking devices such as, but not limited to,hubs, switches, routers, modems, and firewalls.

Two nodes can be said are networked together, when one computing device1400 is able to exchange information with the other computing device1400, whether or not they have a direct connection with each other. Thecommunication sub-module 1462 supports a plurality of applications andservices, such as, but not limited to World Wide Web (WWW), digitalvideo and audio, shared use of application and storage computing devices1400, printers/scanners/fax machines, email/online chat/instantmessaging, remote control, distributed computing, etc. The network maycomprise a plurality of transmission mediums, such as, but not limitedto conductive wire, fiber optics, and wireless. The network may comprisea plurality of communications protocols to organize network traffic,wherein application-specific communications protocols are layered, maybe known to a person having ordinary skill in the art as carried aspayload, over other more general communications protocols. The pluralityof communications protocols may comprise, but not limited to, IEEE 802,ethernet, Wireless LAN (WLAN/Wi-Fi), Internet Protocol (IP) suite (e.g.,TCP/IP, UDP, Internet Protocol version 4 [IPv4], and Internet Protocolversion 6 [IPv6]), Synchronous Optical Networking (SONET)/SynchronousDigital Hierarchy (SDH), Asynchronous Transfer Mode (ATM), and cellularstandards (e.g., Global System for Mobile Communications [GSM], GeneralPacket Radio Service [GPRS], Code-Division Multiple Access [CDMA], andIntegrated Digital Enhanced Network [IDEN]).

The communication sub-module 1462 may comprise a plurality of size,topology, traffic control mechanism and organizational intent. Thecommunication sub-module 1462 may comprise a plurality of embodiments,such as, but not limited to:

-   -   Wired communications, such as, but not limited to, coaxial        cable, phone lines, twisted pair cables (ethernet), and        InfiniBand.    -   Wireless communications, such as, but not limited to,        communications satellites, cellular systems, radio        frequency/spread spectrum technologies, IEEE 802.11 Wi-Fi,        Bluetooth, NFC, free-space optical communications, terrestrial        microwave, and Infrared (IR) communications. Wherein cellular        systems embody technologies such as, but not limited to, 3G, 4G        (such as WiMax and LTE), and 5G (short and long wavelength).    -   Parallel communications, such as, but not limited to, LPT ports.    -   Serial communications, such as, but not limited to, RS-232 and        USB.    -   Fiber Optic communications, such as, but not limited to,        Single-mode optical fiber (SMF) and Multi-mode optical fiber        (MMF).    -   Power Line communications

The aforementioned network may comprise a plurality of layouts, such as,but not limited to, bus network such as ethernet, star network such asWi-Fi, ring network, mesh network, fully connected network, and treenetwork. The network can be characterized by its physical capacity orits organizational purpose. Use of the network, including userauthorization and access rights, differ accordingly. Thecharacterization may include, but not limited to nanoscale network,Personal Area Network (PAN), Local Area Network (LAN), Home Area Network(HAN), Storage Area Network (SAN), Campus Area Network (CAN), backbonenetwork, Metropolitan Area Network (MAN), Wide Area Network (WAN),enterprise private network, Virtual Private Network (VPN), and GlobalArea Network (GAN).

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ the sensors sub-module1463 as a subset of the I/O 1460. The sensors sub-module 1463 comprisesat least one of the devices, modules, and subsystems whose purpose is todetect events or changes in its environment and send the information tothe computing device 1400. Sensors are sensitive to the measuredproperty, are not sensitive to any property not measured, but may beencountered in its application, and do not significantly influence themeasured property. The sensors sub-module 1463 may comprise a pluralityof digital devices and analog devices, wherein if an analog device isused, an Analog to Digital (A-to-D) converter must be employed tointerface the said device with the computing device 1400. The sensorsmay be subject to a plurality of deviations that limit sensor accuracy.The sensors sub-module 1463 may comprise a plurality of embodiments,such as, but not limited to, chemical sensors, automotive sensors,acoustic/sound/vibration sensors, electric current/electricpotential/magnetic/radio sensors,environmental/weather/moisture/humidity sensors, flow/fluid velocitysensors, ionizing radiation/particle sensors, navigation sensors,position/angle/displacement/distance/speed/acceleration sensors,imaging/optical/light sensors, pressure sensors, force/density/levelsensors, thermal/temperature sensors, and proximity/presence sensors. Itshould be understood by a person having ordinary skill in the art thatthe ensuing are non-limiting examples of the aforementioned sensors:

-   -   Chemical sensors, such as, but not limited to, breathalyzer,        carbon dioxide sensor, carbon monoxide/smoke detector, catalytic        bead sensor, chemical field-effect transistor, chemiresistor,        electrochemical gas sensor, electronic nose,        electrolyte-insulator-semiconductor sensor, energy-dispersive        X-ray spectroscopy, fluorescent chloride sensors, holographic        sensor, hydrocarbon dew point analyzer, hydrogen sensor,        hydrogen sulfide sensor, infrared point sensor, ion-selective        electrode, nondispersive infrared sensor, microwave chemistry        sensor, nitrogen oxide sensor, olfactometer, optode, oxygen        sensor, ozone monitor, pellistor, pH glass electrode,        potentiometric sensor, redox electrode, zinc oxide nanorod        sensor, and biosensors (such as nanosensors).    -   Automotive sensors, such as, but not limited to, air flow        meter/mass airflow sensor, air-fuel ratio meter, AFR sensor,        blind spot monitor, engine coolant/exhaust gas/cylinder        head/transmission fluid temperature sensor, hall effect sensor,        wheel/automatic transmission/turbine/vehicle speed sensor,        airbag sensors, brake fluid/engine crankcase/fuel/oil/tire        pressure sensor, camshaft/crankshaft/throttle position sensor,        fuel/oil level sensor, knock sensor, light sensor, MAP sensor,        oxygen sensor (02), parking sensor, radar sensor, torque sensor,        variable reluctance sensor, and water-in-fuel sensor.    -   Acoustic, sound and vibration sensors, such as, but not limited        to, microphone, lace sensor (guitar pickup), seismometer, sound        locator, geophone, and hydrophone.    -   Electric current, electric potential, magnetic, and radio        sensors, such as, but not limited to, current sensor, Daly        detector, electroscope, electron multiplier, faraday cup,        galvanometer, hall effect sensor, hall probe, magnetic anomaly        detector, magnetometer, magnetoresistance, MEMS magnetic field        sensor, metal detector, planar hall sensor, radio direction        finder, and voltage detector.    -   Environmental, weather, moisture, and humidity sensors, such as,        but not limited to, actinometer, air pollution sensor,        bedwetting alarm, ceilometer, dew warning, electrochemical gas        sensor, fish counter, frequency domain sensor, gas detector,        hook gauge evaporimeter, humistor, hygrometer, leaf sensor,        lysimeter, pyranometer, pyrgeometer, psychrometer, rain gauge,        rain sensor, seismometers, SNOTEL, snow gauge, soil moisture        sensor, stream gauge, and tide gauge.    -   Flow and fluid velocity sensors, such as, but not limited to,        air flow meter, anemometer, flow sensor, gas meter, mass flow        sensor, and water meter.    -   Ionizing radiation and particle sensors, such as, but not        limited to, cloud chamber, Geiger counter, Geiger-Muller tube,        ionization chamber, neutron detection, proportional counter,        scintillation counter, semiconductor detector, and        thermoluminescent dosimeter.    -   Navigation sensors, such as, but not limited to, air speed        indicator, altimeter, attitude indicator, depth gauge, fluxgate        compass, gyroscope, inertial navigation system, inertial        reference unit, magnetic compass, MHD sensor, ring laser        gyroscope, turn coordinator, variometer, vibrating structure        gyroscope, and yaw rate sensor.    -   Position, angle, displacement, distance, speed, and acceleration        sensors, such as, but not limited to, accelerometer,        displacement sensor, flex sensor, free fall sensor, gravimeter,        impact sensor, laser rangefinder, LIDAR, odometer, photoelectric        sensor, position sensor such as, but not limited to, GPS or        Glonass, angular rate sensor, shock detector, ultrasonic sensor,        tilt sensor, tachometer, ultra-wideband radar, variable        reluctance sensor, and velocity receiver.    -   Imaging, optical and light sensors, such as, but not limited to,        CMOS sensor, colorimeter, contact image sensor, electro-optical        sensor, infra-red sensor, kinetic inductance detector, LED as        light sensor, light-addressable potentiometric sensor, Nichols        radiometer, fiber-optic sensors, optical position sensor,        thermopile laser sensor, photodetector, photodiode,        photomultiplier tubes, phototransistor, photoelectric sensor,        photoionization detector, photomultiplier, photoresistor,        photoswitch, phototube, scintillometer, Shack-Hartmann,        single-photon avalanche diode, superconducting nanowire        single-photon detector, transition edge sensor, visible light        photon counter, and wavefront sensor.    -   Pressure sensors, such as, but not limited to, barograph,        barometer, boost gauge, bourdon gauge, hot filament ionization        gauge, ionization gauge, McLeod gauge, Oscillating U-tube,        permanent downhole gauge, piezometer, Pirani gauge, pressure        sensor, pressure gauge, tactile sensor, and time pressure gauge.    -   Force, Density, and Level sensors, such as, but not limited to,        bhangmeter, hydrometer, force gauge or force sensor, level        sensor, load cell, magnetic level or nuclear density sensor or        strain gauge, piezocapacitive pressure sensor, piezoelectric        sensor, torque sensor, and viscometer.    -   Thermal and temperature sensors, such as, but not limited to,        bolometer, bimetallic strip, calorimeter, exhaust gas        temperature gauge, flame detection/pyrometer, Gardon gauge,        Golay cell, heat flux sensor, microbolometer, microwave        radiometer, net radiometer, infrared/quartz/resistance        thermometer, silicon bandgap temperature sensor, thermistor, and        thermocouple.    -   Proximity and presence sensors, such as, but not limited to,        alarm sensor, doppler radar, motion detector, occupancy sensor,        proximity sensor, passive infrared sensor, reed switch, stud        finder, triangulation sensor, touch switch, and wired glove.

Consistent with the embodiments of the present disclosure, theaforementioned computing device 1400 may employ the peripheralssub-module 1464 as a subset of the I/O 1460. The peripheral sub-module1464 comprises ancillary devices uses to put information into and getinformation out of the computing device 1400. There are 3 categories ofdevices comprising the peripheral sub-module 1464, which exist based ontheir relationship with the computing device 1400, input devices, outputdevices, and input/output devices. Input devices send at least one ofdata and instructions to the computing device 1400. Input devices can becategorized based on, but not limited to:

-   -   Modality of input, such as, but not limited to, mechanical        motion, audio, visual, and tactile.    -   Whether the input is discrete, such as but not limited to,        pressing a key, or continuous such as, but not limited to        position of a mouse.    -   The number of degrees of freedom involved, such as, but not        limited to, two-dimensional mice vs three-dimensional mice used        for Computer-Aided Design (CAD) applications.

Output devices provide output from the computing device 1400. Outputdevices convert electronically generated information into a form thatcan be presented to humans. Input/output devices perform that performboth input and output functions. It should be understood by a personhaving ordinary skill in the art that the ensuing are non-limitingembodiments of the aforementioned peripheral sub-module 1464:

-   -   Input Devices        -   Human Interface Devices (HID), such as, but not limited to,            pointing device (e.g., mouse, touchpad, joystick,            touchscreen, game controller/gamepad, remote, light pen,            light gun, Wii remote, jog dial, shuttle, and knob),            keyboard, graphics tablet, digital pen, gesture recognition            devices, magnetic ink character recognition, Sip-and-Puff            (SNP) device, and Language Acquisition Device (LAD).        -   High degree of freedom devices, that require up to six            degrees of freedom such as, but not limited to, camera            gimbals, Cave Automatic Virtual Environment (CAVE), and            virtual reality systems.        -   Video Input devices are used to digitize images or video            from the outside world into the computing device 1400. The            information can be stored in a multitude of formats            depending on the user's requirement. Examples of types of            video input devices include, but not limited to, digital            camera, digital camcorder, portable media player, webcam,            Microsoft Kinect, image scanner, fingerprint scanner,            barcode reader, 3D scanner, laser rangefinder, eye gaze            tracker, computed tomography, magnetic resonance imaging,            positron emission tomography, medical ultrasonography, TV            tuner, and iris scanner.        -   Audio input devices are used to capture sound. In some            cases, an audio output device can be used as an input            device, in order to capture produced sound. Audio input            devices allow a user to send audio signals to the computing            device 1400 for at least one of processing, recording, and            carrying out commands. Devices such as microphones allow            users to speak to the computer in order to record a voice            message or navigate software. Aside from recording, audio            input devices are also used with speech recognition            software. Examples of types of audio input devices include,            but not limited to microphone, Musical Instrumental Digital            Interface (MIDI) devices such as, but not limited to a            keyboard, and headset.        -   Data AcQuisition (DAQ) devices convert at least one of            analog signals and physical parameters to digital values for            processing by the computing device 1400. Examples of DAQ            devices may include, but not limited to, Analog to Digital            Converter (ADC), data logger, signal conditioning circuitry,            multiplexer, and Time to Digital Converter (TDC).    -   Output Devices may further comprise, but not be limited to:        -   Display devices, which convert electrical information into            visual form, such as, but not limited to, monitor, TV,            projector, and Computer Output Microfilm (COM). Display            devices can use a plurality of underlying technologies, such            as, but not limited to, Cathode-Ray Tube (CRT), Thin-Film            Transistor (TFT), Liquid Crystal Display (LCD), Organic            Light-Emitting Diode (OLED), MicroLED, E Ink Display            (ePaper) and Refreshable Braille Display (Braille Terminal).        -   Printers, such as, but not limited to, inkjet printers,            laser printers, 3D printers, solid ink printers and            plotters.        -   Audio and Video (AV) devices, such as, but not limited to,            speakers, headphones, amplifiers and lights, which include            lamps, strobes, DJ lighting, stage lighting, architectural            lighting, special effect lighting, and lasers.        -   Other devices such as Digital to Analog Converter (DAC)    -   Input/Output Devices may further comprise, but not be limited        to, touchscreens, networking device (e.g., devices disclosed in        network 1462 sub-module), data storage device (non-volatile        storage 1461), facsimile (FAX), and graphics/sound cards.

All rights including copyrights in the code included herein are vestedin and the property of the Applicant. The Applicant retains and reservesall rights in the code included herein, and grants permission toreproduce the material only in connection with reproduction of thegranted patent and for no other purpose.

IV. CLAIMS

While the specification includes examples, the disclosure's scope isindicated by the following claims. Furthermore, while the specificationhas been described in language specific to structural features and/ormethodological acts, the claims are not limited to the features or actsdescribed above. Rather, the specific features and acts described aboveare disclosed as example for embodiments of the disclosure.

Insofar as the description above and the accompanying drawing discloseany additional subject matter that is not within the scope of the claimsbelow, the disclosures are not dedicated to the public and the right tofile one or more applications to claims such additional disclosures isreserved.

1. A computer program comprising computer code stored in anon-transitory computer readable medium, the computer programcomprising: one or more objects, each object comprising one or moreparameters; and at least one process, each process comprising: aplurality of universal computing elements (UCEs), each universalcomputing element (UCE) comprising: a queue; one or more counters; and afunction, wherein: the queue is configured to accept objects from atleast one of an application programming interface, another UCE, andanother process, the queue is further configured to hold each acceptedobject as a queued object until the queued object is released byapplication of the function, each of the one or more counters isconfigured to represent a status of at least one of the queue and thequeued objects, the function is applied to each queued object based uponat least one of at least one of the one or more counters, and at leastone of the one or more parameters of that queued object, and thefunction comprises at least one of an interconnection identifying one ofthe plurality of UCEs, and an end node function, the interconnectionconfigured to set one of the one or more parameters of a queued objectto which the function is applied to the identified one of the pluralityof UCEs, the computer program comprising computer instructions toperform the following operations: accepting, by a queue of a first UCE,an object; applying, by the first UCE, the function of the first UCE tothe object, the function comprising an interconnection, theinterconnection identifying a second UCE; and releasing, by the queue ofthe first UCE, the object to a queue of the second UCE.
 2. The computerprogram of claim 1, further comprising a dashboard configured to displayone or more metrics, each of the one or more metrics derived from one ofthe one or more counters of one of the plurality of UCEs.
 3. Thecomputer program of claim 2, further comprising a data visualizationelement configured to display graphical data based on the metric.
 4. Thecomputer program of claim 1, wherein the plurality of UCEs comprises atleast three universal computing elements, one of which comprises a startnode, and one of which comprises an end node.
 5. The computer program ofclaim 1, wherein the function of at least one of the plurality of UCEscomprises a plurality of interconnections.
 6. The computer program ofclaim 1, wherein the one or more counters comprise a counter configuredto represent the number of objects in the queue, and a counter for eachobject in the queue representing that object's time of entry into thequeue.
 7. The computer program of claim 1, wherein the function of atleast one of the plurality of UCEs further comprises at least one of:applying a conditional, the conditional comprising at least one of acomparison operator, a logical operator, and a regular expression,copying an object in this process to another process, modifying anobject in another process, an application programming interface call, adatabase call, a call to another process, establishing a queue for useby another process, setting at least one of the one or more parametersof an object in this process, executing code, a mathematical operation,a delay, a call to a code versioning repository, waiting for a response,replying to another process, getting an object from a queue establishedin another process, setting a state, handling error states, issuing analert, a generator of randomness, and a timer.
 8. The computer programof claim 7, wherein the at least one process comprises a first processcomprising a first UCE the function of which is at least one of callinga second process and establishing a queue for use by a second process,the first process further comprising a second UCE the function of whichis waiting for a response from the second process.
 9. The computerprogram of claim 1, wherein the at least one process comprises a firstprocess comprising a first UCE, the function of which is to communicatewith a second process, and a second UCE, the function of which is toawait communication back from the second process.
 10. The computerprogram of claim 1, further comprising a user interface that enablesdrag-and-drop creation, selection, interconnection, and modification ofuniversal computing elements in a process.
 11. The computer program ofclaim 10, wherein the user interface further comprises a visual mappingof each of the process' UCEs and of each interconnection among theprocess' UCEs.
 12. The computer program of claim 10, wherein the userinterface further comprises display of pertinent data and inputs uponselecting a UCE of the process.
 13. The computer program of claim 10,wherein the user interface further comprises automatically creating andinterconnecting a second, error handling UCE upon the creation of afirst UCE.
 14. The computer program of claim 10, further comprising alibrary configured to store and present templates, each templatecomprising a preconfigured collection of UCEs.
 15. A method performed bya platform, the platform comprising: one or more objects, each objectcomprising one or more parameters; and a plurality of processes, eachprocess comprising: a plurality of universal computing elements (UCEs),each universal computing element (UCE) comprising: a queue; one or morecounters; and a function, and at least one interconnection between eachUCE and at least one other UCE, wherein: the one or more objectscomprises a first object and a second object, the plurality of processescomprises a first process and a second process, and the plurality ofUCEs comprises a first UCE of the first process (UCE-1.1), a second UCEof the first process (UCE-1.2), a first UCE of the second process(UCE-2.1), a second UCE of the second process (UCE-2.2), and a third UCEof the second process (UCE-2.3), the method comprising: receiving, byUCE-1.1, from at least one of an application programming interface,another UCE, and another process, the first object; transmitting, byUCE-1.1, information comprising at least one of the one or moreparameters of the first object to UCE-2.1; creating, by UCE-2.1, thesecond object, the second object comprising the at least one of the oneor more parameters of the first object; receiving, by UCE-2.2, thesecond object; transmitting, by UCE-2.2, a request to an applicationprogramming interface (API); setting, by UCE-2.2, at least one of theone or more parameters of the second object based on at least one of asuccessful response from the API, an error response from the API, and alack of response from the API; receiving, by UCE-2.3, the second object;transmitting, by UCE-2.3, information comprising the at least one of theone or more parameters of the second object to UCE-1.2; receiving, byUCE-1.2, the first object; and setting, by UCE-1.2, at least one of theone or more parameters of the first object based on the informationcomprising the at least one of the one or more parameters of the secondobject.
 16. The method of claim 15: wherein the plurality of UCEsfurther comprises an additional UCE (UCE-A), further wherein thefunction of UCE-A comprises at least one of: applying a conditional, theconditional comprising at least one of a comparison operator, a logicaloperator, and a regular expression, copying an object in this process toanother process, modifying an object in another process, an applicationprogramming interface call, a database call, a call to another process,establishing a queue for use by another process, setting at least one ofthe one or more parameters of an object in this process, executing code,a mathematical operation, a delay, a call to a code versioningrepository, waiting for a response, replying to another process, gettingan object from a queue established in another process, setting a state,handling error states, issuing an alert, a generator of randomness, anda timer, further comprising setting, by UCE-A, at least one of the oneor more parameters of at least one of the first object and the secondobject.
 17. The method of claim 15: wherein the second process furthercomprises an error handling loop for UCE-2.2, the error handling loopcomprising an outbound interconnection from UCE-2.2 to a conditionalUCE, an outbound interconnection from the conditional UCE to a delayUCE, and an outbound interconnection from the delay UCE to UCE-2.2,further wherein the setting, by UCE-2.2, of at least one of the one ormore parameters of the second object is based on at least one of anerror response from the API and a lack of response from the API, andfurther comprising receiving, by the conditional UCE, the second object.18. A system comprising: at least one process, each process comprising:a plurality of universal computing elements (UCEs), each universalcomputing element (UCE) comprising: a queue configured accept an objectfrom at least one of an application programming interface, another UCE,and another process, the object configured to be comprise one or moreparameters; one or more counters, each counter configured to represent astatus of at least one of the queue and the object; and a functionapplied to at least one of the counter and the object; and one or moreinterconnections, the one or more interconnections comprising at leastone interconnection between each UCE and at least one other UCE; and aprocessor coupled to a memory element storing executable instructions,the processor executing instructions to configure the system to processobjects through each UCE's queue by applying its function to each suchobject, the processor further executing instructions to pass objectsamong the plurality of UCEs according to the one or moreinterconnections.
 19. The system of claim 18, wherein the at least oneprocess comprises a first process comprising a first UCE, the functionof which is to communicate with a second process, and a second UCE, thefunction of which is to await communication back from the secondprocess.
 20. The system of claim 18, further comprising a user interfacethat enables drag-and-drop creation, selection, interconnection, andmodification of universal computing elements in a process.